Systems and methods for mobile and/or modular manufacturing

ABSTRACT

Systems and methods for manufacturing that are scaleable and de-scaleable based upon the production requirements of the customer&#39;s manufacturing facility. Systems and methods for mobile and/or modular manufacturing positioned at or near a customer&#39;s production facility that are scaleable and de-scaleable based upon the production requirements of the customer&#39;s manufacturing facility. The systems and methods of manufacturing may include identifying a customer&#39;s production requirements at the customer&#39;s production facility, designing a manufacturing cell based upon the identified production requirements, delivering components for the manufacturing cell to a location at or near the customer&#39;s production facility, assembling the components to form the manufacturing cell at the location, and training operational personnel to operate the manufacturing cell. The systems and methods may comprise using a modular preform mold system.

CROSS REFERENCE TO RELATED APPLICATIONS

This application is a continuation of U.S. application Ser. No. 12/127,402 filed May 27, 2008 entitled Systems and Methods for Mobile and/or Modular Manufacturing and of U.S. Application Ser. No. 60/940,309 filed May 25, 2007 entitled System and Method of Mobile Manufacturing, which is herein incorporated by reference in its entirety.

FIELD OF THE INVENTION

The present invention generally relates to systems and methods for mobile and/or modular manufacturing. More particularly, the present invention relates to systems and methods for mobile and/or modular manufacturing that are scaleable and de-scaleable based upon the production requirements of the manufacturing facility.

SUMMARY OF THE INVENTION

Accordingly, the present invention is intended to address and obviate problems and shortcomings and otherwise improve manufacturing processes.

In one exemplary embodiment of the present invention, a method of manufacturing, that includes identifying a customer's production requirements at the customer's production facility, designing a manufacturing cell based upon the identified production requirements, delivering components for the manufacturing cell to a location at or near the customer's production facility, assembling the components to form the manufacturing cell at the location, and training operational personnel to operate the manufacturing cell.

In another exemplary embodiment of the present invention, a method of preform manufacturing comprises identifying a customer's preform production requirements at the customer's production facility, designing a preform injection mold manufacturing cell based upon the identified preform production requirements, delivering components for the preform injection mold manufacturing cell to a location at or near the customer's production facility, assembling the components to form the preform injection mold manufacturing cell at the location, and training operational personnel to operate the preform injection mold manufacturing cell.

BRIEF DESCRIPTION OF THE FIGURES

The following detailed description of exemplary embodiments of the present invention can be best understood when read in conjunction with the following drawings, where like structure is indicated with like reference numerals and in which:

FIG. 1 is a flow diagram of an exemplary embodiment of a method for mobile manufacturing according to the present invention;

FIG. 2 is a schematic representation of an exemplary embodiment of a mobile and/or modular preform manufacturing cell according to the present invention;

FIG. 3a is a perspective view of an exemplary embodiment of a core side of a Preform Mold System according to the present invention connected to a core side of an injection mold machine;

FIG. 3b is a side elevational view of the core side of the Preform Mold System and the injection mold machine of FIG. 3 a;

FIG. 3c is a front view of the core side of the Preform Mold System and the injection mold machine of FIG. 3 a;

FIG. 4a is a perspective view of an exemplary embodiment of a cavity side of a Preform Mold System of according to the present invention connected to a cavity side stationary platen of an injection mold machine;

FIG. 4b is a side elevational view of the cavity side of the Preform Mold System connected to the stationary platen of FIG. 4 a;

FIG. 4c is a front view of the cavity side of the Preform Mold System connected to the stationary platen of FIG. 4 a;

FIG. 4d is a cross sectional view of the cavity side of the Preform Mold System connected to the stationary platen taken along 4 d-4 d of FIG. 4 c;

FIG. 5 is a front view of an exemplary embodiment of four core side preform mold modules according to the present invention, wherein each of the core side preform modules are configured for a different preform design;

FIG. 6a is a perspective view of an exemplary embodiment of a core side module of the Preform Mold System according to the present invention;

FIG. 6b is a top plan view of the core side module of FIG. 6 a;

FIG. 6c is a cross sectional view of the core side module taken along 6 c-6 c of FIG. 6 b;

FIG. 6d is a cross sectional view of the core side module taken along 6 d-6 d of FIG. 6 b;

FIG. 7a is a perspective view of an exemplary embodiment of a cavity side module of the Preform Mold System according to the present invention;

FIG. 7b is a top plan view of the cavity side module of FIG. 7 a;

FIG. 7c is a cross sectional view of the cavity side module taken along 7 c-7 c of FIG. 7 b;

FIG. 7d is a cross sectional view of the cavity side module taken along 7 d-7 d of FIG. 7 b;

FIG. 8a is a top plan view of an exemplary embodiment of a single preform mold stack-up according to the present invention, wherein a core is inserted into a cavity to form a preform mold;

FIG. 8b is a cross sectional view of the preform mold stack-up taken along 8 b-8 b of FIG. 8 a;

FIG. 9a is a perspective view of an exemplary embodiment of an ejector housing assembly according to the present invention;

FIG. 9b is an exploded view of the ejector housing assembly of FIG. 9 a;

FIG. 9c is a side elevational of the ejection housing assembly of FIG. 9 a;

FIG. 9d is a top plan view of the ejection housing assembly of FIG. 9 a;

FIG. 10a is a perspective view of an exemplary embodiment of a cavity portion of the cavity side module according to the present invention;

FIG. 10b is a side elevational of the cavity portion of FIG. 10 a;

FIG. 10c is a top plan view of the cavity portion of FIG. 10 a;

FIG. 10d is a bottom plan view of the cavity portion of FIG. 10 a;

FIG. 10e is a cross sectional view of the cavity portion taken along 10 e-10 e of FIG. 10 d;

FIG. 10f is a detail view of the cavity portion taken at 10 f of FIG. 10 e;

FIG. 10g is a detail view of the cavity portion taken at 10 g of FIG. 10 e;

FIG. 11a is a perspective view of an exemplary embodiment of a thread split according to the present invention;

FIG. 11b is a bottom plan view of the thread split of FIG. 11 a;

FIG. 11c is a side elevational of the thread split of FIG. 11 a;

FIG. 11d is a top plan view of the thread split of FIG. 11 a;

FIG. 11e is a cross sectional view of the thread split taken along 11 e-11 e of FIG. 11 d;

FIG. 12a is a top plan view of an exemplary embodiment of a cavity plate of the cavity side module of FIG. 7 a;

FIG. 12b is a bottom plan view of the cavity plate of FIG. 12 a;

FIG. 12c is a detail view of the cavity plate taken at A of FIG. 12 a;

FIG. 12d is a detail view of the cavity plate taken along 12 c-12 c of FIG. 12 a;

FIG. 12e is a detail view of the cavity plate taken along 12 d-12 d of FIG. 12 a;

FIG. 13a is a perspective view of an exemplary embodiment of an ejector plate of the core side module of FIG. 6 a;

FIG. 13b is a top plan view of the ejector plate of FIG. 13 a;

FIG. 13c is a side elevational view of the ejector plate of FIG. 13 a;

FIG. 13d is a cross sectional view of the ejector plate taken along 13 d-13 d of FIG. 13 b;

FIG. 13e is a cross sectional view of the ejector plate taken along 13 e-13 e of FIG. 13 b;

FIG. 13f is a cross sectional view of the ejector plate taken along 13 f-13 f of FIG. 13 b;

FIG. 14a is a perspective view of an exemplary embodiment of a core plate of the core side module of FIG. 6 a;

FIG. 14b is a top plan view of the core plate of FIG. 14 a;

FIG. 14c is a cross sectional view of the core plate taken along 14 c-14 c of FIG. 14 b;

FIG. 15a is a top plan view of an exemplary embodiment of a left carrier plate of the core side module of FIG. 6 a;

FIG. 15b is a side elevational view of the left carrier plate of FIG. 15 a;

FIG. 15c is a bottom plan view of the left carrier plate of FIG. 15 a;

FIG. 15d is view of the left carrier plate taken along 15 d-15 d of FIG. 15 c;

FIG. 15e is a cross sectional view of the left carrier plate taken along 15 e-15 e of FIG. 15 c;

FIG. 15f is a cross sectional view of the left carrier plate taken along 15 f-15 f of FIG. 15 c;

FIG. 15g is a view of the left carrier plate taken along 15 g-15 g of FIG. 15 c;

FIG. 16a is a top plan view of an exemplary embodiment of a right carrier plate of the core side module of FIG. 6 a;

FIG. 16b is a side elevational view of the right carrier plate of FIG. 16 a;

FIG. 16c is a bottom plan view of the right carrier plate of FIG. 16 a;

FIG. 16d is view of the right carrier plate taken along 16 d-16 d of FIG. 16 c;

FIG. 16e is a cross sectional view of the right carrier plate taken along 16 e-16 e of FIG. 16 c;

FIG. 16f is a cross sectional view of the right carrier plate taken along 16 f-16 f of FIG. 16 c;

FIG. 16g is a view of the right carrier plate taken along 16 g-16 g of FIG. 16 c;

FIG. 17a is a top plan view of an exemplary embodiment of a first half section of the clamp plate of FIG. 1;

FIG. 17b is a cross section view of the first half section of the clamp plate taken along 17 b-17 b of FIG. 17 a;

FIG. 17c is a cross section view of the first half section of the clamp plate taken along 17 c-17 c FIG. 17 a;

FIG. 18 is a top plan view of an exemplary embodiment of a second half section of the clamp plate of FIG. 3;

FIG. 19a is a perspective view of the first and second half sections of FIGS. 14 and 15 connected to form the clamp plate shown in FIG. 3;

FIG. 19b is an end view of the second half section of FIG. 18;

FIG. 20a is a top plan view of an exemplary embodiment of a wear plate of the core side module of FIG. 6 a;

FIG. 20b is a side elevational view of the wear plate of FIG. 20 a;

FIG. 21a is a top plan view of an exemplary embodiment of a gib of the core side module of FIG. 6 a;

FIG. 21b is a side elevational view of the gib of FIG. 21 a;

FIG. 21c is a front view of the gib of FIG. 21 a;

FIG. 21d is a cross section view of the gib taken along A-A of FIG. 21 c;

FIG. 22a is top plan view of an exemplary embodiment of a core sleeve of the core side module of FIG. 6 a;

FIG. 22b is a side elevational view of the core sleeve of 22 a;

FIG. 22c is a cross sectional view of the core sleeve taken along 22 c-22 c of FIG. 22 a;

FIG. 22d is a detail of the core sleeve taken at 22 d of FIG. 22 c;

FIG. 22e is a detail of the core sleeve taken at 22 e of FIG. 22 c;

FIG. 23a is top plan view of an exemplary embodiment of a filler plate of the cavity side module of FIG. 7 a;

FIG. 23b is a front view of the filler plate of 23 a; and

FIG. 23c is a side elevational view of the filler plate of FIG. 23 a.

The embodiments set forth in the drawings are illustrative in nature and not intended to be limiting of the invention defined by the claims. Moreover, individual features of the drawings and the invention will be more fully apparent and understood in view of the detailed description.

DETAILED DESCRIPTION OF THE INVENTION

The following text sets forth a broad description of numerous different embodiments of the present invention. The description is to be construed as exemplary only and does not describe every possible embodiment since describing every possible embodiment would be impractical, if not impossible, and it will be understood that any feature, characteristic, component, composition, ingredient, product, step or methodology described herein can be deleted, combined with or substituted for, in whole or part, any other feature, characteristic, component, composition, ingredient, product, step or methodology described herein. Numerous alternative embodiments could be implemented, using either current technology or technology developed after the filing date of this patent, which would still fall within the scope of the claims. All publications and patents cited herein are incorporated herein by reference.

The present invention generally relates to systems and methods for manufacturing. More particularly, the present invention relates to systems and methods for mobile and/or modular manufacturing that is scaleable and/or de-scaleable based upon the changing requirements of the production facility. Even more particularly, the present invention relates to systems, methods, and/or a business model for mobile and/or modular plastic preform manufacturing at or near the customer's facility.

The present invention may be a customized, adaptable, mobile, portable, and flexible manufacturing system and method (e.g., preform injection molding system) operable to be located at a customer's facilities (i.e., on-site) or near the customer's facilities (e.g., warehouse or production facilities near customer's facility). The present invention is highly capable of producing products for the customer on-site or near the customer's facilities (near on-site), with no in-house investment, personnel, or expertise required. The system and method of the present invention may comprise a method of integrating mobile preform manufacturing modules, which can be quickly located within or in close proximity to a customer's (or supplier's) site or facility and enabling flexible, low-cost, high volume, highly adaptable production capabilities (capable of manufacturing a variety of preform sizes, shapes, and numbers, simultaneously or sequentially).

The present invention may eliminate the need for the traditional large plant infrastructure and corresponding capital investment expenditures. The present invention also may enable the reduction and/or elimination of the supply chain and/or costs due to packaging, shipping, and fuel. Also, the present invention provides for an improved level of support and services that may be real-time or just-in-time compared with a traditional large plant that is located across the state or country.

The complete system offers the customer quality manufactured products (e.g., preforms/parisons), services, and support (the “products”) matched to the unique user's requirements. The system and method's mobility attribute supports quick expansion, relocation, and/or reduction capabilities.

As used herein, the term ‘manufacturing cell’ means a manufacturing cell that is mobile and/or modular such that components of the manufacturing cell may be transported to or near a customer's production facility and assembled into a functioning manufacturing cell such as a preform injection molding process. The manufacturing cell may be quickly and efficiently scaleable or de-scaleable based upon the changing customer production requirements. When the customer no longer requires the manufacturing cell at or near its production facility, the manufacturing cell may be disassembled and removed from the location.

As used herein, the terms ‘preform’ and ‘parison’ mean a test tube shaped part produced by injection mold systems, as known to one of ordinary skill in the art, in a first step of a two-stage injection molding and blow molding process used to produce bottles or containers. The injection molding of a preform/parison may be performed in an injection mold machine as known to one of ordinary skill in the art. In the preform, the bottle-cap threads are already molded into place, and the body of the tube is significantly thicker, as it will be inflated into its final shape in the second step using stretch-blow molding. In a second process, the preforms are heated rapidly and then inflated against a two-part mold to form them into the final shape of the bottle or container. In some applications, preforms (uninflated bottles) may be used as containers.

Preform design, as used herein, is defined as a specific shape, size, and/or finish of a preform.

As used herein, the term ‘provider’ means an entity (e.g., a company, corporation, partnership, or any other corporate form), its employees or representatives, an individual, one or more individuals, sole proprietor, or any combination thereof that provides and/or performs for a customer the systems and methods of the present invention.

An exemplary embodiment of the mobile and modular manufacturing system and method of the present invention that may be provided, assembled, and performed by a provider of such system and method is shown in FIG. 1. In the exemplary method, an extensive requirements determination process is performed with a customer. The Provider may request and then receive from the customer information regarding product requirements and/or specifications, including preform sizes, forecasts, and inventory levels. If the customer does not provide the product requirements and/or specifications, the Provider may also generate production specifications based upon prior history, history of a similar product and drawings, and/or industry standard(s). Additionally, the requirements identification process may include a requirements (and/or specification) identification interview, wherein one or more employees or other representatives of the customer may be extensively interviewed to determine the customer's production and/or manufacturing requirements (e.g., required preform shapes, sizes, volume, materials, etc.) and to learn how the mobile manufacturing system and method of the present invention would best be adapted and/or customized to the specific requirements of the user. The requirements identification interview may include preparing and/or customizing a series of questions to be presented to the customer that are industry-specific and/or customer-specific. Once the product requirements and/or specification(s) are developed and/or determined, the Provider may supply this product specification to the customer for review, comment, and/or approval. If the production involves a colored product, color plagues may be provided to the customer as well.

Following the extensive requirements identification process and/or interview and/or the customer's approval of the product specification, a design team guides, advises, and ultimately creates a mobile and/or modular manufacturing cell (e.g., mobile manufacturing system) to manufacture products (e.g., preforms) at or in near proximity to the customer's site (e.g., production facilities, warehouse, etc.) that meet the customer's requirements for volume, quality, value, and just-in-time availability. This mobile and/or modular manufacturing cell is easily and efficiently scaleable and de-scaleable in response to the changing customer's production demands.

In an exemplary embodiment, the mobile and/or modular manufacturing cell generally may comprise one or more phase production sections and a base systems section comprising system equipment that may be used with the one or more phase production sections as the manufacturing cell is either expanded or reduced in capacity based upon the customer's changing production requirements as will be described in greater detail below with reference to an exemplary embodiment. The mobile and/or modular manufacturing cell may comprise manufacturing machines/equipments, monitoring equipment, monitors, and systems, and/or computers that are modular and designed such that the system may easily and efficiently be modified to adjust capacity of production and shape and size of the product being produced to the changing production requirements of the customer. As such, the exemplary mobile manufacturing system, including the mobile manufacturing cell, utilizes and takes advantage of quick connect/disconnect connections and hoses, snap fit connections, adjustable manifolds, module mold plates/platens, adjustable valve gate systems, and/or any combinations thereof as known to one of ordinary skill in the art. As set forth above, the mobile and/or modular manufacturing cell of the present invention may be configured to produce a variety of different types of products, and thus comprise a variety of different types of machines and/or equipment, including but not limited to injection molding machines, blow molding machines, and/or thermoforming machines.

Referring to FIG. 2, an exemplary mobile and/or modular manufacturing cell is shown as mobile and modular preform manufacturing cell 1000. Preform manufacturing cell 1000 may comprise a base systems section 1001 and a phase I production section 1002. Base systems section 1001 may be configured to support phase I production section 1002 and/or one or more additional phase production sections such as a phase II production and phase III production sections as the customer's production requirements change, e.g., grow or reduce.

Base systems section 1001 may comprise one or more electrical switchgear 1030, a process water cooling system 1040, and/or a regrind process 1020. Process water cooling system 1040 provides cooling to the injection machine and molds and a dryer process as known to one of ordinary skill in the art. The injection machine will have a water cooled feed throat section as well as cooling for the hydraulic systems on the machine. These items, along with the return air cooling coils of the dryers, can be operated on a tower water utility. The mold cooling, as well as any chilling requirements for robot preform cooling, will require chilled water. These requirements form the basis of the process cooling water needs.

A tower water system can readily provide cooling water at about 80° F. In this type of cooler, water is recirculated through an atmospheric cooling tower similar to those used at electrical power plans. Although much smaller in size, an industrial tower water system consists of the same elements as a larger one. The tower assembly sprays water through a series of baffles to allow evaporative cooling of the water. As a result, about 3% of the water volume in the system will be lost to evaporation and will require makeup water from the facility water supply. Once the water has been cooled in the tower, it is brought up to pressure in a centrifugal pump. The pump discharge is connected to the distribution piping system and plumbed to the individual use points.

At each device using the cooling water, shutoff valves and appropriate disconnect devices should be used to enable any one item to be isolated from the distribution system. Parallel to the supply water pipe will be a second pipe to return the used water to the cooling tower where the loop starts over. Tower water systems may require the use of additives to control corrosion and limit scale buildup. Since the evaporative tower is open to the elements, a biocide is normally used to prevent the growth of mold and any other microbes that will live in a warm, dark, wet areas. These controls are important to maintain a trouble free water cooling system.

To remove heat from a mold (e.g., modular preform molds), chilled water at about 60° F. may be used to remove the thermal energy in the melted resin. In order to depress the temperature of cooling water below what is available with evaporative cooling methods, a refrigerant based chilling system is employed as known to one of ordinary skill in the art. These systems may use common refrigerants to remove energy from a circulating water system and may typically transfer the excess heat to the tower water system. A chilled water system may employ a refrigerant compressor, air or water cooled condenser for removing the excess energy from the refrigerant, and an evaporator heat exchanger to cool the circulating water. Construction of a chilled water system may employ a single frame to hold the refrigerant system along with the heat exchangers and water circulating pumps. Most packaged commercial systems will have a redundant water pump available for circulating water to avoid system loss due to a pump failure.

Both tower and chilled water systems may use a reservoir tank to equalize the system operating pressure. This tank may be sized based on the total gallons recirculated in the system and will have a make up valve and overflow pipe to manage the water volume in the system. In tower water systems, water conditioners may be necessary and monitored and adjusted based on the amount of makeup water introduced into the system. On chilled water systems the water is trapped in a closed loop so losses are minimal. Proper water condition may be required, but is not subject to the changes of a continuous makeup dilution.

While the mobile manufacturing cell 1000, by its design and operations, may be configured to minimize the production of scrap, there may be times of production loss or off-specification production. This scrap material, which may consist of whole or partial preforms and/or bottles and/or excess material that is cut from the preforms or bottles, may be reground and introduced back into the production process to the greatest extent possible. Regrind process and/or system 1020 as shown in FIG. 2 may be configured to receive all the captured excess plastic from the preform injection mold process and/or blowmolding process, regrind it, and then prepare it to be recycled back into the preform injection mold and/or blowmolding process. The conservation and re-use of raw materials provides the mobile and/or modular manufacturing cell substantial benefits, including but not limited to reducing raw material costs and minimizing the manufacturing cell's impact on the environment.

The selection of a grinder to perform the regrinding of the plastic will be determined based on the production capacity of the mobile manufacturing cell 1000 and whether bottle scrap product will be ground and re-introduced. This analysis of grinding opportunities may be one aspect of the requirements identification process and/or interview conducted with the customer as shown in FIG. 1. Once volume requirements are determined, the grinder may be selected based on its regrind chip size capabilities. The grinder controls the chip size by a selection of a “screen” element that is part of the grinding chamber. These openings will control the size of the regrind. To ensure uniform, free flowing regrind, in one exemplary embodiment, a ⅜″ screen size may be used to minimize fine generation in the grinder. A high flow fan may also be added to increase more air flow into the grinder and the grinding process. This will reduce the heat produced during the grinding operation, which may negatively impact regrind quality. The grinder may be any grinder commercially available and as known to one of ordinary skill in the art.

Grinder knives should be kept sharp and properly gapped. The grinding system, of the mobile and/or modular manufacturing cell 1000, may be located as close to the mobile cell as possible. Plastic sheeting curtains, versus hardened walls, separate and protect the manufacturing cell from the grinding system. These curtains will permit easy expansion or disassembly of the grinding operation as required.

The first step of an exemplary regrind process 1020 may comprise the dumping and/or loading of scrap preforms and/or bottles into a hopper (not shown) that feeds a belt conveyor (not shown) going up to the inlet of the grinder. This dumping and/or loading step may comprise an automatic step, wherein the scraps are fed from a conveyor to the hopper and then dumped into the hopper automatically. Alternatively, an operator may manually dump the scraps into the hopper which then supplies the scraps to the belt conveyor that then feeds the scraps to the grinder to be ground. The hopper and the one or more conveyors may be any commercially available hopper and conveyors as known to one of ordinary skill in the art.

Proper illumination along the conveyor may assist in enabling quality inspections and sorting by the operator. The operator may inspect materials and reject any unacceptable product. An installed switch, can divert unacceptable product from the conveyor to an adjacent container, i.e., a deflector chute (not shown). A metal detector may also be installed as part of the in-feed conveyor belt. The metal detector may sense both ferrous and non-ferrous metals. Acceptable material may then pass through the grinder and be discharged into another material conveyor. This conveyor may transport the material to the inlet of a dust removal system. This device uses a counter flow of air to lift the dust particles from the ground granules, allowing the regrind to fall through and go forward in the process. The dust may be pulled off with the air stream and sent to an adjacent dust collector. Once the dedusting stage is complete, the ground material will free fall into a secondary metal detector. As before, a small amount of ground material may be lost with activation of the metal contaminant diverter.

Once the grinding process is complete, the regrind material will be stored, to be re-introduced later in the manufacturing process. Regrind may be stored in boxes or storage surge bins. Base systems section 1001 may also comprise a maintenance section for placement and/or storage of maintenance items.

Phase I production section 1002 may comprise one or more manufacturing or production equipment such as a preform injection mold machine 1010, monitoring sensors, and/or other production equipment. Other exemplary manufacturing equipment that may be included with the mobile and/or manufacturing cell may include, but are not be limited to, injection molding machines, blow molding machines, injection-blow molding machines, thermoforming machines, molds, and/or mold systems, particularly those configured for manufacturing plastic preforms, plastic bottles, containers, and/or other products from the preforms.

Such exemplary manufacturing equipment may comprise molding machines and components shown and describe in one or more of the following U.S. Pat. Nos. 4,202,522; 4,219,323; 4,268,240; 4,330,257; 4,395,222; 4,412,806; 5,533,883; 5,536,164; 5,620,723; 5,738,149; 5,863,485; 6,082,991; 6,123,891; 6,135,757; 6,143,215; 6,220,850; 6,726,465; 6,749,779; and/or 7,037,103, which are all herein incorporated by reference in their entirety. Also, an exemplary embodiment of the mobile manufacturing cell may comprise the mixing method and apparatus for injection molding machines as shown and described in U.S. Patent Application Publication No. 2002/0105113, which is herein incorporated by reference in its entirety. Preform injection mold machine 1010 may comprise a Husky 300 ton injection molding machine or a Husky 600 ton injection molding machine commercially available from Husky Injection Molding Systems Ltd.

Referring to FIGS. 3 thru 23, the system and method of the present invention may also comprise a modular preform mold system 10 (hereinafter “Peform Mold System 10”) that is operable to connect to and function with preform injection mold machine 1010 in either a new or retro-fit installation. Preform Mold System 10 may comprise the preform mold system as shown and described in a commonly-owned, co-pending U.S. application Ser. No. 11/829,326 filed Jul. 27, 2007 and titled “Apparatus and Methods For Modular Preform Mold Systems,” which is herein incorporated by reference in its entirety.

Preform mold system 10 may be configured to enable flexible, low-cost, high volume, highly adaptable production capabilities (capable of manufacturing a variety of preform sizes, shapes, and numbers, simultaneously or sequentially). This exemplary Preform Mold System in combination with the system and method of the present invention may offer the customer quality manufactured preforms/parisons (the “products”) matched to the unique customer's production requirements on-site or in a location in close proximity to the customer's facility. Due to its modularity and flexibility, the system and method of the present invention, including the Preform Mold System 10, reduces and/or eliminates the need for second injection mold machines for molding preforms having a different size, shape, and/or finish (design) simultaneously or without requiring mold change-outs. Thus, the Preform Mold System, as set forth above, reduces or eliminates added capital investment, unused production capacity, and stranded investment. Also, the Preform Mold System 10 permits the injection mold machine to efficiently, cost effectively, and quickly adapt and/or change to the ever changing production requirements of the customer and the market. In one exemplary embodiment of the Preform Mold System (i.e., mold) of the present invention, the Preform Mold System may operate in conjunction with or be retrofitted to a single injection mold machine to simultaneously produce a plurality of preforms (i.e., products) having a multitude of preform designs (“sizes, shapes, and/or finishes”) on this single injection mold machine.

Preform Mold System 10 generally comprises a core side 40 (e.g., FIGS. 3, 5, and 6) and a corresponding cavity side 100 (e.g., FIGS. 3 and 7). The Preform Mold System 10 of the present invention may include multiple preform core side modules 20 (e.g., a first core side module 20 a, a second core side module 20 b, a third core side module 20 c, a fourth core side module 20 d), multiple cavity side modules 50 (e.g., a first cavity side module 50 a, a second cavity side module 50 b, a third cavity side module 50 c, a fourth cavity side module 50 d) corresponding to the respective core side modules 20, a core side clamp plate 34 operable to receive and connect to one or more of core side modules 20, wherein the multiple core side modules 20 and the respective multiple cavity side modules 50 are designed and/or operable to matingly engage one another to form multiple preform mold stack-up modules having multiple preform molds 67. Also, Preform Mold System 10 may, optionally, include a manifold and valve gate assembly 111 operable to receive and connect to one or more of cavity side modules 50 and to control and direct the injection of fluidized plastic into each preform mold 67 disposed within each mold stack-up module of the present invention that is actually connected to clamp plate 34 and manifold and valve gate assembly 111.

Also, Preform Mold System 10 may comprise an ejector housing assembly 70 (e.g., a first ejector housing assembly 70 a, a second ejector housing assembly (not shown), a third ejector housing assembly 70 c, a fourth ejector housing assembly 70 d) for each the core side module 20 (e.g., 20 a, 20 b, 20 c, 20 d). Each ejector housing assembly 70 connects between core side clamp plate 34 and an ejector platen 42 of a core side 45 of injection mold machine 1010 and connects to each core side module 20 a, 20 b, 20 c, 20 d.

Generally, preform injection mold machine 1010 comprises a core side 45 and a cavity side (“hot side”) 105 as known to one of ordinary skill in the art. For illustrations purposes only, and not limitation, FIG. 3 shows an exemplary embodiment of core side 40 of Preform Mold System 10 connected to core side 45 of injection mold machine 1010. Specifically, clamp plate 34 is operable to receive and connect to one or more of core side modules 20 (e.g., 20 a, 20 b, 20 c, 20 d) and connects the core side modules to a moving platen 44 of core side 45 of injection mold machine 1010. Specifically, core side modules 20 are connected to clamp plate 34 using bolts that are connected into bolt holes disposed within clamp plate 34. The bolts and bolt holes are positioned such that they are accessible in the press of the injection mold machine. Such easy bolt on and off connectivity of core side modules 20 from clamp plate 34 of Preform Mold System 10 provide quick mold change out and adaptability capabilities to injection mold machine 1010, thus reducing long production down times due to lengthy mold change outs. Clamp plate 34 of the present invention is connected to moving platen 44 of the injection mold machine using toe clamps as known to one of ordinary skill in the art.

As shown in FIG. 1, three core side modules 20 a, 20 c, 20 d are shown attached to the core side clamp plate 34, leaving an open position B on clamp plate 34 available to receive second core side module 20 b if desired, although not required to run the system to mold preforms. Although the exemplary embodiment only shows clamp plate 34 configured to receive and/or connect to four core side modules 20 a, 20 b, 20 c, 20 d, it is understood that the core side clamp plate may be configured to receive a plurality of core side modules, depending upon the preform design, number of preform cores 6 per module, etc. For example, clamp plate 34 shown in FIG. 1 may be replaced with a different clamp plate (not shown) configured to receive and/or connect to up to six core side modules.

Also for illustration purposes only, and not limitation, FIG. 2 shows an exemplary embodiment of cavity side 100 of Preform Mold System 10 connected to a cavity side 105 of injection mold machine 1010. Specifically, manifold and valve gate assembly 111 is operable to receive one or more of cavity side modules 50 (e.g., 50 a, 50 b, 50 c, 50 d) and connect the modules 50 to a stationary platen 115 of cavity side 105 of the injection mold machine. Manifold and valve gate assembly 111 also places the cavity side modules 50 a, 50 b, 50 c, 50 d in fluid communication with an injector (not shown) of the injection mold machine. In addition, manifold and valve gate 111 is operable to distribute and control from the injector a uniform flow of fluidized plastic to each preform mold 67 of each attached preform mold stack-up module. Manifold and valve gate assembly 111 is balanced as known to one of ordinary skill in the art to deliver the same pressure to each preform mold 67 of the Preform Mold System 10. Although the exemplary embodiment only shows four cavity side modules 50 a, 50 b, 50 c, 50 d connected to and in fluid communication with manifold and valve gate assembly 111, it is understood that the manifold and valve gate assembly 111 may be configured and operable to receive any number of cavity side modules 50, depending upon the preform design, number of preform cavities 56 per module, and size of the injection mold machine. For example, manifold and valve gate assembly 111 shown in FIG. 2 may receive up to six cavity side modules 50.

Manifold and valve gate assembly 111 are designed to modify and control the fluidized plastic's flow from the injection mold machine to each preform mold 67. When combined with the machine parameters for injection pressure, melt temperature, and other injection and operational parameters the Preform Mold System 10 of the present invention enables a single injection mold machine to inject fluidized plastic into each distinctly sized, shaped, and/or finished preform mold 67 (e.g., core/cavity combination) in a uniform flow. As such, Preform Mold System 10 is capable of molding (or forming) multiple preform designs simultaneously with a single injection mold machine.

As known to one of ordinary skill in the art and schematically shown in FIG. 1, core side 45 of the injection mold machine also may comprise a clamp unit 46 connected to both an ejector platen 42 and moving platen 44. The injection mold machine may include an ejector activation system (not shown) that are connected to ejector platen 42, and may or may not be connected to ejector housing assemblies 70 of the present invention. It is understood that a variety of commercially available injection mold machines as known to one of ordinary skill in the art may be used with Preform Mold System 10 of the present invention, including but not limited to molding machines and components shown and describe in one or more of the following U.S. Pat. Nos. 4,202,522; 4,219,323; 4,268,240; 4,330,257; 4,395,222; 4,412,806; 5,533,883; 5,536,164; 5,620,723; 5,738,149; 5,863,485; 6,082,991; 6,123,891; 6,135,757; 6,143,215; 6,220,850; 6,726,465; 6,749,779; and/or 7,037,103, which are all herein incorporated by reference. Two exemplary molding machines that the Preform Mold System 10 of the present invention may be operable to connect to and function with includes, but are not limited to, a HUSKY 300 ton injection mold machine or a HUSKY 600 ton injection mold machine commercially available from HUSKY Injection Molding Systems Ltd.

Each of the core side modules 20 may comprise a plurality of cores 6, extending outwardly from the core side module (e.g., FIGS. 5 and 6). Referring to FIGS. 3, 5, 6, 11, and 13-16, an individual core side module 20 is shown and described in detail below. When the core side module 20 is assembled, the core plate 1 serves as a base, a base end 6 b of the sixteen cores 6 are inserted into the apertures 35 of the core plate 1 such that a flange 6 a of the cores 6 rests upon a top surface 6 c of the core plate 1. The sixteen core sleeves 11 are then slid onto the sixteen cores 6 such that flange 37 of the core sleeves 11 rests upon the core plate 1 and the flange 6 a of the cores 6. The ejector plate 22 is then position upon the flange 37 such that the cores 6 and respective core sleeves 11 are inserted into each of the apertures 48 of the sleeves 11. The wear plate 25 is then positioned upon the ejector plate 22 such that the cores 6 are inserted through and the sleeves 11 extend through.

Next, the left and right carrier plates 29 and 30 are positioned upon the wear plate 25 such that the cores 6 extend through apertures 39. The thread splits 32 are slid over the cores 6 such that the cores 6 insert through apertures 47 and then connected to the left and right ejector plates such that the thread splits 32 are positioned relative to the cores 6 to create the thread finish. Two gibs 27, shown in FIGS. 3, 6, and 16, are connected to opposite ends of the ejector plate 22 and engage opposite ends of the left and right plate carriers 29 and 30, respectively, and assist in holding the core side module 20 together. As assembled, the apertures 35, 38, 48, 39, 47, 49 are coaxially aligned coaxially with each other. The core side modules 20 also comprise two Y-Cams 14 that are connected to opposite ends of the core plate 1 and that extend through the ejector plate 22 and the left and right carrier plates and two return cams 16 positioned opposite each other along each Y-Cam as shown. These Y cams create the opening of the threadsplits that is required to eject or remove the finish molded preform.

Also, each cavity side module 50 may comprise a plurality of cavities 56 disposed therein corresponding to each core 6 of the respective core side module (e.g., FIG. 5). Referring now to FIGS. 4, 7, 10, 12, and 23, an exemplary embodiment of the cavity side module 50 is shown. The cavity side module 50 comprises a cavity plate 51 that comprises a plurality of apertures 62 (e.g., sixteen staggered apertures disposed in two rows of eight) disposed therein and along the plate 51 such that the apertures align with the respective cores 6 of the core side module 20 when the two modules are placed into mating engagement with each other as set forth above. A plurality of cavity portions 56 are inserted into each of the apertures 62 and attached to the plate 51. The cavity side module 50 comprises thirty two baffle cavities 57 (which equals two baffle cavities per cavity portion 56), ninety-six baffle cavities 58 (which equals six baffle cavities per cavity portion 56), and thirty-two baffle cavities 59 (which equals two baffle cavities per cavity portion 56).

Each cavity portion 56 comprises a shaped chamber 63 that is configured to receive the respective cores 6 such that the combination of the shape chamber 63 and the inserted core 6 forms the mold chamber 65, creating a specific preform design. At each end of the cavity plate 51 and disposed upon its top surface are two filler blocks 61 as shown in FIGS. 4, 7, and 10. The cavity side module also includes two self lube bushings 53 within an opening through the cavity plate 51, forty-four connectors 60, sixteen o-rings 52 positioned around a base of each cavity 56, eighteen brass pipe plugs, and sixteen o-rings 55 positioned around an upper portion of each cavity 56 as shown in FIG. 6.

As set forth above, each of the core side modules 20 (e.g., first core side module 20 a, second core side module 20 b, third core side module 20 c, and fourth core side module 20 d) and respective cavity side modules 50 (e.g., first cavity side module 50 a, second cavity side module 50 b, third cavity side module 50 c, and fourth cavity side module 50 d are configured to matingly engage one another, forming respective preform mold stack-up modules (first mold stack-up module, second mold stack-up module, third mold stack-up module, and fourth mold stack-up module). Each preform mold stack-up module may comprise a plurality of preform molds 67 disposed therein formed by the plurality of core 6/cavity 56 combinations (e.g., preform mold 67 shown in FIG. 6).

As an example, when Preform Mold System 10 is connected to injection mold machine 1010, a clamping system (e.g., moving platen 44) of the injection mold machine can move core side modules (e.g., 20 a, 20 b, 20 c, 20 d) into mating engagement with cavity side modules (e.g., 50 a, 50 b, 50 c, 50 d), wherein the plurality of cores 6 of the core side modules are inserted into the plurality of respective cavities 56 of the cavity side modules to form the preform molds 67 within the four preform mold stack-up modules. FIG. 6b shows a cross section of a representative single mold stack-up, wherein a single core 6 is inserted into a single cavity 56 having a preform mold chamber 65 therebetween, forming the preform mold 67.

A fluidized plastic may be injected by the injector of the mold machine through the manifold and valve gate assembly 111 into the preform mold chambers 65 of each preform mold 67 of each preform mold stack-up module to form a plurality of plastic preforms having one or more preform designs or the same preform design. Due to the separate preform mold modules of Preform Mold System 10 being separately connectable and disconnectable to a single injection mold system, the present invention transforms and enables a single convention injection mold machine to form (mold) multiple preform designs simultaneously and to be adjustable as to its production output. For example, and not limitation, first core side module 20 a and respective first cavity side module 50 a may be designed to form a preform having a first preform design 110A, second core side module 20 b and respective second cavity side module 50 b may be designed to form a preform having a second preform design 110B, third core side module 20 c and respective third cavity side module 50 c may be designed to form a preform having a third preform design 110C, and fourth core side module 20 d and respective fourth cavity side module 50 d may be designed to form a preform having a fourth preform design 110D. Although not shown in FIGS. 3 and 4, the exemplary embodiment of the Preform Mold System 10 may permit a fifth and a sixth preform mold module to be connected to it. As such, the individual mold stack-up modules can be configured such that first preform design 110A, second preform design 110B, third preform design 110C, fourth preform design 110D, fifth preform design (not shown), and sixth preform design (not shown) are all different from each other as shown in FIG. 3, all the same, or some combination thereof. As will be explained below herein, Preform Mold System 10 of the present invention is configured such that it enables a single injection mold machine to mold one or more preform designs simultaneously, or sequentially. Each preform design may be assessed through mold flow analysis as known to one of ordinary skill in the art to determine the fill characteristics required (injection pressure and fill time) to mold the different preforms having the specific designs.

The quantity of preform molds 67 per preform mold stack-up module is based upon preform size and weight, and balanced material flow. The exemplary embodiment of Preform Mold System 10 comprises sixteen preform molds 67 per preform mold stack-up module (e.g., sixteen cores 6 per first core side module 20 a/and sixteen cavities 56 per first cavity side module 50 a). In the exemplary embodiment, the sixteen cores 6 are disposed in two rows of eight staggered cores 6 per core side module. The exemplary embodiment also may include sixteen cavities 56 disposed in respective two rows of eight staggered cavities 56 per cavity side module.

As shown, the clamp plate (e.g., 34) and manifold and valve gate assembly 111 are operable to receive four of these core side modules and four of these cavity side modules, respectively. Also, manifold and valve gate assembly 111 is operable to uniformly control and distribute the fluidized plastic into each of the preform molds 67 of one or more the preform mold stack-up modules that are attached to the injection mold machine. As such, the exemplary embodiment of Preform Mold System 10 may comprise from one to four mold stack-up modules comprising from sixteen preform molds (67) to sixty-four preform molds (67) that may be connected to injection mold machine 1010. Such a configuration of Preform Mold System 10 enables one injection mold machine to form from sixteen preforms to sixty-four preforms and from one to four different preform designs, simultaneously or sequentially, which conventional injection mold machines are not capable of doing.

As another example, clamp plate 34 may be configured to receive and connect to up to six core side modules 20 of Preform Mold System 10. In addition, Preform Mold System may comprise six respective cavity side modules 50 corresponding to the core side modules. As shown in FIGS. 6 and 7, both core side modules 20 and cavity side modules 50 may comprise sixteen staggered cores 6 and sixteen staggered cavities 56, respectively. Thus, each of the six core side modules 20 are operable to matingly engage with one of the six cavity side modules 50 to form sixteen preform molds 67 per preform mold stack-up module. Also, manifold and valve gate assembly 111 is operable to uniformly control and distribute the fluidized plastic into each of the preform molds 67 of one or more the preform mold stack-up modules that are attached to the injection mold machine. As such, the exemplary embodiment of Preform Mold System 10 may comprise from one to six mold stack-up modules comprising from sixteen preform molds (67) to ninety-six preform molds (67) that may be connected to injection mold machine 1010. In such a configuration, Preform Mold System 10 enables one injection mold machine to form from sixteen preforms to ninety-six preforms and from one to four different preform designs, simultaneously or sequentially, which conventional injection mold machines are not capable of doing.

It is understood that the quantity of molds per stack-up module and the configuration may vary, depending upon the preform design. Other exemplary embodiments of Preform Mold System 10 may comprise a total number of preform molds 67 (i.e., cavitation) of 4, 8, 16, 32, 48, 64, 80, 96, 100 molds, or more. In addition, the molds 67 may be positioned in other configurations such as inline rather than staggered.

Also, the number of preform mold modules that may be included with Preform Mold System 10 may be based on injection mold machine size (shot size, clamp size and clamp tonnage). As an alternative exemplary embodiment, the preform system 10 may comprise core side modules that comprise twenty cores 6, staggered in two rows of ten cores, and respective cavity side modules that comprise twenty respective cavities 56, staggered in two rows of ten cavities. In such an embodiment, clamp plate 34 and manifold and valve gate assembly 111 are operable to receive five of these core side modules and five of these cavity side modules, respectively. Also, manifold and valve gate assembly 111 is operable to uniformly control and distribute the fluidized plastic into each of the preform molds 67 of one or more the preform mold stack-up modules that are attached to the injection mold machine. Thus, in this exemplary embodiment, Preform Mold System 10 enables a single injection mold machine to form from twenty to one hundred preforms and from one to five different preform designs, simultaneously or sequentially.

As shown in FIGS. 3 and 9, the Preform Mold System 10 may include an ejector housing assembly 70 for each core side module 20. Each ejector housing assembly 70 (e.g., first ejector housing assembly 70 a, third ejector housing assembly 70 c, fourth ejector housing assembly 70 d) is connected between the machine ejector plate 42 and the core side clamp plate(s) 34. An end of each ejector housing assembly 70 inserts through a hole in the clamp plate 34 and connects to each preform mold module 20 such that each ejector housing assembly 70 may move its respective preform mold module individually and separately to provide an equal or shorter ejection stroke than the ejector platen 42 on the press of the injection mold machine. This permits the ejection of preforms of different designs (i.e., lengths and finishes) by utilizing the ejection housing assembly 70 for each mold stack-up module to assist the press ejection system in ejecting each preform from the preform molds 67. Also, each ejector housing assembly 70 is easily connected and disconnected via bolt connections from the ejector plate 42 and the core side clamp plate 34 as known to one or ordinary skill in the art to permit simple and efficient change-outs and adaptation to changing production requirements.

Phase I production section 1002 may also comprise a dryer 1050 as known to one of ordinary skill in the art and thus no need to be described in great detail herein. Dryer 1050 may be used to provide process drying of the raw material resin in preparation for the preform injection mold process. At this point in the system, all of the available water carried by the resin is removed by dryer 1050. This may be accomplished with the application of adequate temperature with the corresponding exposure time and air quality. All these conditions, if not properly maintained at the proper levels, may cause the manufacturing cell 1000 to produce a substandard product. Dryer 1050 may comprise a dehumidified hopper dryer (not shown) with high temperature process options. Such a dehumidified hopper dryer is commercially available and as known to one of ordinary skill in the art.

In drying, there are four principle factors. First, adequate airflow may be necessary to carry thermal energy to the resin, and provide enough air exchanges to carry away all of the water. The second element in drying may be the dryness or dewpoint of the air entering the process drying hopper. Dewpoint is defined as the temperature at which 100 percent relative humidity exists. The third aspect of drying may be temperature. The drying temperature should be selected as to not fuse the resin in the vessel while still removing all of the water available within the resin. An operator may balance the airflow, dewpoint and temperature such that there are each at the acceptable ranges.

The fourth aspect of the drying process is the drying hopper. There are several functions performed by this relatively simple appearing vessel. First, the size of the vessel is selected to give the desired holding or dwell time for the drying to take place. If the vessel is undersized, then un-dried resin may proceed to the molding machine. Conversely, it may not be desirable to have a wide range of drying times which would be exacerbated by an overly large dryer.

As shown in FIG. 2, as the customer's production requirements increase, manufacturing cell 1000 may include a phase II production section 1003, a phase III production section 1004, or any number of additional phase production sections as required. It is understood that the phase II production, phase III production, and any additional phase production sections may include the same or substantially similar equipment as phase I production section 1002 or include different equipment for manufacturing a different product. Manufacturing cell 1000 may be a customized and modular system.

Next, one or more facilities and equipment technicians may procure and assemble, at the selected site of the customer, the highly efficient, specific-to-the-customer mobile manufacturing system and cell 1000. All equipment and supplies required for the system are chosen based on their mobility and adaptability for quick expansion, reduction, assembly, disassembly, and/or relocation capabilities. During the above step, operational personnel necessary to operate the preform manufacturing system are recruited and hired.

Once hired, the personnel are trained on the preform manufacturing system. Generally, this training may be preformed off-site from the customer's location on similar equipment and materials. In one exemplary embodiment, the off-site training is provided at a central site such as the provider of the mobile manufacturing system and method, wherein similar equipment is set up for customer training. It is understood that this training may be provided and performed at the customer's final location, i.e., the location where the customized mobile manufacturing system ultimately be located.

Chart I set forth below shows and describes an exemplary embodiment of the training provided and included in the system and method of the present invention. Specifically, Chart I shows an exemplary individual training record that may be provided to one or more of the operational personnel (e.g., an operator and assistant operator of the mobile manufacturing system). The individual training record of Chart I includes numerous headings which detail key information regarding the training of the mobile manufacturing system operator and/or assistant operator.

CHART I Operator & Assistant Operator Employee Name: Docu- Train- Operator Train- Original ment Vali- ing & Em- er Train- or Training Num- Type dation Approved Course Fre- Assistant ployee Ini- ing Refresher Course ber of Doc Document Name Source Trainers Hours quency Operator Initials tials Date Training HRS 6300 SAF EMERGENCY Q DIRECTORS 0.5 Y P INFORMATION BOOK HRS 6307 SAF PLANT EVACUATION Q DIRECTORS 0.3 Y P HRS 6341 SAF SHELTER Q DIRECTORS 0.3 Y P HRS 6346 SAF HIGH DEW POINT Q DIRECTORS 0.3 Y P HRS 6446 SAF HIGH DEW POINT- Q DIRECTORS 0.3 Y P MANAGER ON-CALL HRS 101 0 0 OWNS TOOLS D DIRECTOR 0.1 I P NECESSARY TO OF HR PERFORM WORK HRS 101 0 0 LOCKOUT/TAGOUT D MAINTE- 1 I P SYSTEM INSTRUCTIONS NANCE MGR. HRS 101 002 WI MSDS PROCESS D DIRECTOR 0.4 I P OF HR HRS 101 6006 FM EYE PROTECTION D DIRECTOR 0.1 I P ISSUING FORM OF HR HRS 101 7020 TR FORKLIFT: PEDESTRIAN Q DIRECTOR 0.5 I P SAFETY (video) CROWN OF HR HRS 101 7022 TR FORKLIFT: SAFETY DIRECTOR 1 I P (video) OF HR HRS 101 7024 TR HAZARD COMMUNI- D DIRECTOR 0.4 I P CATION (video) OF HR HRS 101 7025 TR MSDS (video) D DIRECTOR 0.4 I P OF HR HRS 101 7026 TR LOCKOUT/TAGOUT Q DIRECTOR 0.4 I P AWARENESS OF HR (powerpoint) HRS 101 7029 TR 5S TRAINING VIDEO D HUMAN 1.2 I P RESOURCE DIRECTOR HRS 101 8001 EMP EMPLOYEE HANDBOOK D DIRECTOR 0.2 I P OF HR HRS 201 603 REF EMERGENCY CONTACT D DIRECTOR OF 0.2 I P NUMBERS OPERATIONS/ DIRECTOR OF QUALITY HRS 201 3003 FM LOCKOUT/TAGOUT/ D MAINTE- 1 I P TAG OUT TEST FORM NANCE MGR. HRS 201 3004 FM SAFETY LOCK D MAINTE- 0.2 I P ASSIGNMENT FORM NANCE MGR. HRS 201 6001 FM ITR (INDIVIDUAL DIRECTOR 0 O P TRAINING RECORD) OF HR BLANK HRS 401 8123 FM JOB DESCRIPTION D DIRECTORS 0.5 I P MNT 101 308 WI LOCKOUT TAG OUT Q & D MAINTE- 2 Y P double check agsinst NANCE MGR. 6803 MNT 101 322 WI VACUUM PUMP FILTER D MAINTE- 0.5 I P CLEANING NANCE MGR. MNT 101 1013 FM VIRGIN/REGRIND D MAINTE- 0.5 I P SET-UPS NANCE MGR. MNT 101 1024 FM CAVITATION CHANGE D INJ.MOLD 0.3 I P FORM MGR. MNT 101 3014 FM MAINTENANCE D MAINTE- 2 I P TECHNICIAN CHECKLIST NANCE MGR. MNT 101 3100 FM CONVEYOR BELT PM D MAINTE- 4 I P CHECKLIST NANCE MGR. MNT 101 3108 FM SILO CLEANING D RESIN 1 I P CHECKLIST UNLOADING SUPERVISO MNT 201 303 WI WATER HOSE D MAINTE- 1 I P CONNECTION NANCE MGR. INSTRUCTIONS MNT 201 314 WI CLEANING GUIDLINES- D MAINTE- 2 I P HUSKY PRESS 14 NANCE MGR. MNT 201 315 WI CLEANING GUIDLINES- D MAINTE- 2 I P HUSKY PRESS 15 NANCE MGR. MNT 201 3015 FM HUSKY MOLD PM D INJ. MOLD 0 O P PROCEDURE MGR. MNT 201 6005 FM TOOL LAYOUT CHART D INJ. MOLD 0 O P MGR. MNT 401 3020 FM PRESS PREVENTIVE D MAINTE- 0.3 I P MAINTENANCE NANCE MGR. PROGRAM-SCHEDULE OPS 101 006 REF SHIFT TRANSITION D INJ. MOLD 0.5 Y P BRIEFING MGR. OPS 101 100 REF INJECTION MOLD D INJ. MOLD 4 Y P TRAINING 101 MGR.

Column 1 of Chart I above describes the category and level of the training course. BUS signifies a Business Course; HRS signifies a Human Resource Services Course; MNT signifies a Maintenance Course; OPS signifies an Operations Course; QUA signifies a Quality Course; SRW signifies a Shipping, Receiving, and Warehouse Course; and SYS signifies a Systems Course. Courses are offered at different levels, i.e. 101 is an entry level, 201 is a greater technical level, 301 is a highly technical level, and 401 is at the management or specialist level.

Column 2 provides the unique document number used to manage the documents.

Column 3 describes what kind of document it is, i.e. WI signifies a Work Instruction, FM signifies the document is a form, REF signifies the document is a reference document, TR signifies the document is a training document, EMP signifies the document is in the employee handbook, SAF signifies the document is in the safety handbook, and PFD signifies the document is a Process Flow Diagram.

Column 4 details the document name.

Column 5 states how the training will be validated, i.e. by either D for demonstration or Q for a quiz.

Column 6 states the approved trainer for the specific course.

Column 7 states the estimated time the course will take to complete.

Column 8 states the frequency of the training, i.e. S indicates the course must be completed prior to being hired; P indicates the course is a competency course and must be performed prior to being qualified in the position; and A or blank signifies the employee in this position must only be aware of the existence of this course and it has no competency need.

The remaining columns, columns 9 thru 12, are fields for the employee and trainer to initial when the training is complete.

An operator and assistant operator must complete all S and P courses and have their training validated (D or Q) before they are considered qualified.

Either simultaneously to or sequentially with the hiring and initial training of the manufacturing personnel, the mobile and/or manufacturing cell may be constructed at the customer's site or at a site in close proximity to the customer's production site. The Provider as part of the method of the present invention may also provide all the construction design, request for proposal preparation, evaluation, and approval, subcontractor and construction management and oversight, budget estimation, review, and approval, and/or any other processes, steps, or items related to the construction and testing of the mobile and/or modular manufacturing cell of the present invention. Once the mobile and/or modular manufacturing cell is built, the Provider will run a sample production run, and then supply the customer will a product sample and the test run's data for evaluation and/or approval.

When the mobile manufacturing system (e.g., mobile preform manufacturing system) is ready for start-up production, the trained operations personnel (e.g., operator(s) and/or assistant operator(s)) are brought to the final location and trained on-site on the customized mobile manufacturing system (e.g., mobile preform manufacturing system) specifically designed to meet the defined customer requirements.

The mobile and/or modular manufacturing system and method of the present invention also offers immediate, responsive on-site support and services by industry experts in all aspects of the customers' operation. This immediate, responsive on-site support and services may be provided in a variety of methods. Exemplary methods that may be used include, but are not limited to, providing on-site personnel (e.g., provider personnel, trained customer personnel, etc.), real-time customer support via a network, intranet, the Internet, telephone, other customer support contact options, system monitoring (e.g., on-site and remote), and/or any combinations thereof.

For example, the system and method of the present invention may include a monitoring system that is operable to monitor the mobile manufacturing system and its operational parameters on-site and/or from a remote location (e.g., a central location, provider's remote facilities). The system may be operable to monitor, alarm, track, and record the operational run time, down time, failure rates, production volume, flow rates, fill pressure, cycle time, and/or any other operational or system functions and/or parameters for the whole manufacturing system and/or any individual component. Such monitoring systems and components may be comprise conventional monitoring systems and components as known to one of ordinary skill in the art and be assembled and customized to meet the specific customer's requirements.

One exemplary monitoring system may comprise real time process monitoring of the mobile and/or modular manufacturing cell or cells and may be viewed from any computer terminal. The monitoring system software is programmed to comprise color coding in order to provided the status of a current job(s) or mold press(es). On the monitor screen, the field for either the job or press will turn colors according to the status of the respective job and/or press. For example, the color “Green” may indicate that all the monitored parameters for the job(s) and/or press(es) are within the specified limits. The color “Red” may indicate that one or more of the monitored parameters for the job(s) and/or press(es) have exceeded its specification limits. The color “Yellow” may indicate that the job(s) and/or press(es) has not cycled within its non-production limit. The color “Blue may indicate that there is no active job for that specific press. Finally, the color “Purple” may indicate that the monitoring unit is not communicating with the host computer.

The system and method of the present invention may also comprise a monitoring system capable of real time monitoring parameters and cycle times of one or more of the machines in the manufacturing cell. The software may include fields for cycle time and other machine parameters that may be viewable on any computer terminal. These fields may turn colors according to the status of the monitored parameters. For example, the color “Green” may indicate that all the monitored process parameters are within the specified limits. The color “Red” may indicate that one or more of the monitored parameters has exceeded its specification limit. The color “White” may indicate that one or more of the monitored parameters is running below the specified limit.

Additionally, the system and method of the present invention may also comprise a monitoring system that also performs real time monitoring for Yield Efficiency of a certain job. The software may be programmed to calculate, provide, and display a yield efficiency for one or more jobs and be color coded to provide the status of the efficiency of the one or more jobs. For example, the color “Green” may indicate that the job is performing within its expected yield limits. The color “Red” may indicate that the job is performing below the expected yield limit, which reflects inefficiency in the process. The color “White” may indicate that the job is performing above the expected yield limit, which reflects a more efficient process. It is understood that a variety of colors, conditions, indicators, and monitoring configurations may be used with the present invention.

The system performs the functions described above as a stand alone system.

If, and when the manufacturing system is no longer needed and required on-site by the customer, the system can be quickly dismantled and removed from the on-site location. The mobile manufacturing system's mobility attribute supports quick expansion, relocation, or reduction capabilities. The complete system and method offers a customer quality product (e.g., preforms), services, and support (the “products and services”) according to parameters and requirements collected from the user. Mobile Manufacturing establishes and operates complete preform production matched to the unique customer's requirements. The system will reduce or eliminate capital investment expenditures; shorten the supply chain; accommodate and react to just-in-time requirements; and ultimately, manage the cost of the manufactured preforms.

All documents cited in the Detailed Description of the Invention are, in relevant part, incorporated herein by reference; the citation of any document is not to be construed as an admission that it is prior art with respect to the present invention. To the extent that any meaning or definition of a term in this written document conflicts with any meaning or definition of the term in a document incorporated by reference, the meaning or definition assigned to the term in this written document shall govern.

While particular embodiments of the present invention have been illustrated and described, it would be obvious to those skilled in the art that various other changes and modifications can be made without departing from the spirit and scope of the invention. It is therefore intended to cover in the appended claims all such changes and modifications that are within the scope of this invention. 

What is claimed:
 1. A mold stack-up module comprising: a core module comprising: a core plate, and a plurality of cores extending from the core plate, wherein the plurality of cores are positioned along the core plate in two or less rows and comprise a first row of cores positioned along the core plate and a second row of cores positioned adjacent to and staggered from the first row of cores along the core plate; and a cavity module comprising: a cavity plate, and a plurality of shaped chambers disposed in the cavity plate, wherein the plurality of shaped chambers are positioned along the cavity plate in two or less rows and comprise a first row of shaped chambers disposed within the cavity plate and a second row of shaped chambers disposed within the cavity plate, adjacent to and staggered from the first row of chambers; wherein the core module and cavity module matingly engage each other such that each one of the plurality of shaped chambers receives a respective one of the plurality of cores to form a respective mold chamber.
 2. The mold stack-up module of claim 1, wherein the respective mold chamber defines a preform.
 3. The mold stack-up module of claim 1, wherein: the first row of cores comprises eight cores positioned along the core plate and the second row of cores comprises eight cores positioned adjacent to and staggered from the first row of eight cores along the core plate; and the first row of shaped chambers comprises eight shaped chambers disposed within the cavity plate and the second row of chambers comprises eight shaped chambers disposed within the cavity plate, adjacent to and staggered from the first row of eight chambers.
 4. The mold stack-up module of claim 3, wherein the first row of eight cores and second row of eight cores matingly engaged with the first row of eight shaped chambers and second row of eight shaped chambers, respectively, to form eight mold chambers and eight mold chambers, respectively.
 5. A method of molding a plurality of preforms using a single plastic injection mold machine, the method comprising: using one to six mold stack-up modules according to claim 1; and forming sixteen to one hundred preforms having one to six distinct preform designs simultaneously.
 6. A mold stack-up module kit, the kit comprising: a first mold stack-up module for forming a first preform design, the first mold stack-up module comprising: a first core module comprising; a core plate, and a plurality of cores extending from the core plate, wherein the plurality of cores are positioned along the core plate in two or less rows and comprise a first row of cores positioned along the core plate and a second row of cores positioned adjacent to and staggered from the first row of cores along the core plate, and a first cavity module comprising: a cavity plate, and a plurality of shaped chambers disposed in the cavity plate, wherein the plurality of shaped chambers are positioned along the cavity plate in two or less rows and comprise a first row of shaped chambers disposed within the cavity plate and a second row of shaped chambers disposed within the cavity plate, adjacent to and staggered from the first row of chambers, wherein the first core module and first cavity module matingly engage each other such that each one of the plurality of shaped chambers receives a respective one of the plurality of cores to form a respective mold chamber shaped to form the first preform design; and a second mold stack-up module for forming a second preform design, the second mold stack-up module comprising: a second core module comprising; a core plate, and a plurality of cores extending from the core plate, wherein the plurality of cores are positioned along the core plate of the second core module in two or less rows and comprise a first row of cores positioned along the core plate of the second core module and a second row of cores positioned adjacent to and staggered from the first row of cores along the core plate of the second core module, and a second cavity module comprising: a cavity plate, and a plurality of shaped chambers disposed in the cavity plate, wherein the plurality of shaped chambers are positioned along the cavity plate of the second cavity module in two or less rows and comprise a first row of shaped chambers disposed within the cavity plate of the second cavity module and a second row of shaped chambers disposed within the cavity plate, adjacent to and staggered from the first row of chambers along the cavity plate of the second cavity module, wherein the second core module and second cavity module matingly engage each other such that each one of the plurality of shaped chambers receives a respective one of the plurality of cores to form a respective mold chamber shaped to form the second preform design which is different than the first preform design.
 7. The kit of claim 6, further comprising a third mold stack-up module for forming a third preform design, the third mold stack-up module comprising: a third core module comprising; a core plate, and a plurality of cores extending from the core plate, wherein the plurality of cores are positioned along the core plate in two or less rows; and a third cavity module comprising: a cavity plate, and a plurality of shaped chambers disposed in the cavity plate, wherein the plurality of shaped chambers are positioned along the cavity plate in two or less rows; wherein the third core module and third cavity module matingly engage each other such that each one of the plurality of shaped chambers receives a respective one of the plurality of cores to form a respective mold chamber shaped to form the third preform design which is the same as or different than the first and second preform designs.
 8. The kit of claim 7, further comprising a fourth mold stack-up module for forming a fourth preform design, the fourth mold stack-up module comprising: a fourth core module comprising; a core plate, and a plurality of cores extending from the core plate, wherein the plurality of cores are positioned along the core plate in two or less rows; and a fourth cavity module comprising: a cavity plate, and a plurality of shaped chambers disposed in the cavity plate, wherein the plurality of shaped chambers are positioned along the cavity plate in two or less rows; wherein the fourth core module and fourth cavity module matingly engage each other such that each one of the plurality of shaped chambers receives a respective one of the plurality of cores to form a respective mold chamber shaped to form the fourth preform design which is the same as or different than the first, second, and third preform designs.
 9. The kit of claim 7, wherein the third preform design is different than the first and second preform designs.
 10. The kit of claim 8, wherein the first, second, third, and fourth preform designs are all different from each other.
 11. A mold stack-up module comprising a core side module configured to matingly engage a respective cavity side module, wherein the core side module comprises: a plurality of outwardly extending cores arranged in a staggered conformation wherein each of the plurality of outwardly extending cores comprises a base end; a core plate comprising apertures through which the base end of the plurality of outwardly extending cores are inserted such that the outwardly extending cores extend from a top surface of the core plate; a plurality of core sleeves each comprising an aperture into which the outwardly extending cores are inserted, each of the plurality of core sleeves comprising a flange which abuts the core plate; an ejector plate positioned upon the flanges of the core sleeves, the ejector plate comprising apertures through which the plurality of outwardly extending cores and core sleeves extend therethrough; a wear plate positioned upon the ejector plate, the wear plate comprising apertures through which the plurality of outwardly extending cores and core sleeves extend therethrough; a left and a right carrier plate positioned upon the wear plate comprising apertures through which the plurality of outwardly extending cores extend therethrough; wherein the ejector plate is secured to both the left and the right carrier plate by a plurality of gibs positioned at opposite ends of the ejector plate; thread splits comprising apertures through which the plurality of outwardly extending cores extend therethrough wherein the thread splits are connectable to the ejector plate; a pair of y-cams, comprising a pair of return cams, positioned at opposite ends of the carrier plates; wherein the core plate apertures, the ejector plate apertures, the left and the right carrier plate apertures, and the thread split apertures are all coaxially aligned; and wherein the cavity side module comprises: a cavity plate comprising a plurality of staggered apertures corresponding to the plurality of outwardly extending cores of the respective core side module; and a plurality of cavity portions inserted into the staggered apertures and attached to the cavity plate, each cavity portion comprising a shaped chamber configured to receive the outwardly extending cores such that the mating of the shaped chamber and the outwardly extending core forms a preform mold comprising a mold chamber having a specific preform design.
 12. The mold stack-up module of claim 11, wherein the cavity plate comprises sixteen staggered apertures disposed in two rows of eight.
 13. The mold stack-up module of claim 12, wherein the core play comprises sixteen staggered apertures disposed in two rows of eight that correspond with the sixteen staggered apertures of the cavity plate.
 14. The mold stack-up module of claim 11, wherein each cavity portion comprises baffle cavities.
 15. A method of molding preforms on a single plastic injection mold machine, the method comprising: forming a plurality of preforms having a first preform design using a first mold stack-up module, the first mold stack-up module comprising: a first core module comprising; a core plate, and a plurality of cores extending from the core plate, wherein the plurality of cores are positioned along the core plate in two or less rows and comprise a first row of cores positioned along the core plate and a second row of cores positioned adjacent to and staggered from the first row of cores along the core plate, and a first cavity module comprising: a cavity plate, and a plurality of shaped chambers disposed in the cavity plate, wherein the plurality of shaped chambers are positioned along the cavity plate in two or less rows and comprise a first row of shaped chambers disposed within the cavity plate and a second row of shaped chambers disposed within the cavity plate, adjacent to and staggered from the first row of chambers, wherein the first core module and first cavity module matingly engage each other such that each one of the plurality of shaped chambers receives a respective one of the plurality of cores to form a respective mold chamber shaped to form the first preform design; and forming a plurality of preforms having a second preform design using a second mold stack-up module, the second mold stack-up module comprising: a second core module comprising; a core plate, and a plurality of cores extending from the core plate, wherein the plurality of cores are positioned along the core plate of the second core module in two or less rows and comprise a first row of cores positioned along the core plate of the second core module and a second row of cores positioned adjacent to and staggered from the first row of cores along the core plate of the second core module, and a second cavity module comprising: a cavity plate, and a plurality of shaped chambers disposed in the cavity plate, wherein the plurality of shaped chambers are positioned along the cavity plate of the second cavity module in two or less rows and comprise a first row of shaped chambers disposed within the cavity plate of the second cavity module and a second row of shaped chambers disposed within the cavity plate, adjacent to and staggered from the first row of chambers along the cavity plate of the second cavity module, wherein the second core module and second cavity module matingly engage each other such that each one of the plurality of shaped chambers receives a respective one of the plurality of cores to form a respective mold chamber shaped to form the second preform design, which is different than the first preform design.
 16. The method of claim 15, further comprising forming a plurality of preforms having a third preform design using a third mold stack-up module, the third mold stack-up module comprising: a third core module comprising; a core plate, and a plurality of cores extending from the core plate, wherein the plurality of cores are positioned along the core plate in two or less rows, and a third cavity module comprising: a cavity plate, and a plurality of shaped chambers disposed in the cavity plate, wherein the plurality of shaped chambers are positioned along the cavity plate in two or less rows, wherein the third core module and third cavity module matingly engage each other such that each one of the plurality of shaped chambers receives a respective one of the plurality of cores to form a respective mold chamber shaped to form the third preform design, which is the same as or different than the first and second preform designs.
 17. The method of claim 16, further comprising forming a plurality of preforms having a fourth preform design using a fourth mold stack-up module, the fourth mold stack-up module comprising: a fourth core module comprising; a core plate, and a plurality of cores extending from the core plate, wherein the plurality of cores are positioned along the core plate in two or less rows, and a fourth cavity module comprising: a cavity plate, and a plurality of shaped chambers disposed in the cavity plate, wherein the plurality of shaped chambers are positioned along the cavity plate in two or less rows, wherein the fourth core module and fourth cavity module matingly engage each other such that each one of the plurality of shaped chambers receives a respective one of the plurality of cores to form a respective mold chamber shaped to form the fourth preform design, which is the same as or different than the first, second, and third preform designs.
 18. The method of claim 17, wherein the first, second, third, and fourth preform designs are all different from each other. 